Preparation, structure, and spectroscopy of cobalt (III) complexes

Preparation, structure, and spectroscopy of cobalt(III) complexes containing N,N'-di-8-quinolyl derivatives of 1,2-diaminoethane, (R)-1,2-diaminopropa...
0 downloads 0 Views 779KB Size
Inorg. Chem. 1983, 22, 2048-2054

2048

Contribution from the Chemistry Department, Faculty of Science, Tohoku University, Aoba, Aramaki, Sendai 980, Japan

Preparation, Structure, and Spectroscopy of Cobalt(111) Complexes Containing N,N’-Di-8-quinolyl Derivatives of 1,2-Diaminoethane, ( R )-1,2-Diaminopropane, and ( R,R )-1,2-Diaminocyclohexane TOSHISHIGE M. SUZUKI,’ SIGERU OHBA,2 SHOICHI S A T 0 , 3 YOSHIHIKO S A I T 0 , 2 and KAZUO SAITO* Received April 12, 1982

Mixed-ligand cobalt(II1) complexes have been prepared by the reaction of tris(acetylacetonato)cobalt(III) with an N,N’-di-8-quinolyl- 1,2-diaminoaIkane ( 1,2-diaminoethane, (R)-1,2-diaminopropane, and (R,R)-1,2-diaminocyclohexane) in organic solvents. The isolated complexes have deprotonated secondary amino nitrogens. The parent complexes with neutral ligands were readily formed on addition of hydrogen chloride in organic solvents, but the crystals were isolated with difficulty. The absorption, CD, and ‘H N M R spectra change rapidly and reversibly on protonation and deprotonation of the quadridentate ligand. The X-ray crystal structure analysis of [Co(acac)(R-dqpn’)]C104,which contains the deprotonated form of dqpn (dqpn = N,N’-di-8-quinolyl- 1,2-diaminopropane), has been performed in order to clarify the detailed structure. Crystal = data: COC106N4C26H26, 0 = 11.112 (2) A, b = 13.299 (5) A, C = 9.275 (4) A, a = 106.06 (4)O, @ = 88.72 (3)’, 85.87 (3)O, space group P 1 , Z = 2, R = 5.7% for 4327 observed reflections. The two independent complex cations consist of the A- and A-isomers. The stereochemistry including geometrical and optical isomerism of both the protonated and deprotonated complexes is discussed on the basis of the crystal structure and spectroscopic data in solution. The quadridentate ligands seem to undergo rapid rearrangement on protonation and deprotonation of the complexes.

Much attention has been drawn to the cobalt(II1) complexes with multidentate ligands structurally intermediate between Most of the ligands so aliphatic and aromatic far used in the preparation of cobalt(II1) complexes, however, have been limited to pyridine derivatives. 2-Pyridylmethylamine:,’ 1-(2-pyridyl)ethylamine,9-’2 and their quadridentate derivative^^^^^*^^^-^^ have partial aromatic character, but the spectroscopic and stereochemical properties of their cobalt(II1) complexes are essentially the same as those with aliphatic diamines. Reaction of various aliphatic diamines with 8-quinolinol gives linear quadridentate ligands in which two amino groups are linked by 8-quinolyl rings.16 Nielsen and Dahl prepared N,N’-di-8-quinolyl derivatives of ethylenediamine and trimethylenediamine and studied the IR and visible absorption spectra of their copper(I1) and nickel(I1) complexes.” One of the present authors studied the CD spectra of copper(I1) complexes of related optically active ligands shown in Figure la’* In the present study we have prepared cobalt(II1) complexes with these ligands. Reaction of tris(acety1acetonato)cobalt(II1) with the ligand in organic solvent gave a dark purple compound containing the quadridentate ligand in the deprotonated form, [Co(acac)(deprotonated dqdm)]+ (acac = acetylacetonato ion; dqdm = N,N’-di-8-quinolyl- 1,2-diaminoalkane; hereinafter deprotonated dqdm is expressed by Government Industrial Research Institute, Tohoku, Haranomachi, Sendai 983, Japan. Department of Chemistry, Faculty of Science and Technology, Keio University, Hiyoshi-3, Kohoku-ku, Yokohama 223, Japan. Institute for Solid State Physics, University of Tokyo, Roppongi-7, Minatoku, Tokyo 106, Japan. Michelsen, K. Acta Chem. Scand. 1970, 24, 2003. Bosnich, B.; Kneen, W. R. Inorg. Chem. 1970, 9, 2191. Gibson, J. G.; McKenzie, E. D. J . Chem. SOC.A 1971, 1666. Michelsen, K. Acta Chem. Scand. 1972, 26, 769. Cragle, J., Jr.; Brubaker, G. R. Inorg. Chem. 1972, J I , 303. Michelsen, K. Acta Chem. Scand., Ser. A 1974, A28, 428. Suzuki, T. M.; Watanabe, Y.; Fujita, J.; Saito, K. Bull. Chem. SOC.Jpn. 1975, 48, 1947. Michelsen, K.; Pedersen, E. Acta Chem. Scand., Ser. A 1978, A32,847. Ito, M.; Ohba, S.;Sato, S.; Saito, Y. Acta Crystallogr., Secr. B 1981, 837, 1405. Utsuno, S.;Hayashi, A.; Kondo, S.; Utsumi, M. Chem. Lett. 1979, 351. Suzuki, T. M.; Kimura, T.; Fujita, J. Bull. Chem. SOC.Jpn. 1980,53,

17. Ohba, S.;Sato, S.;Saito, Y. Acta Crystallogr., Secf.B 1981, 837, 80. Jensen, K. A.; Nielsen, P. H. Acta Chem. Scand. 1964, 18, 1 . Nielsen, P. H.; Dahl, 0. Acta Chem. Scand. 1966, 20, 11 13. Suzuki, T. M.; Kamiyama, S.; Kimura, T. Bull. Chem. SOC.Jpn. 1978, 51, i094. 0020-1669/83/ 1322-2048$01.50/0

dqdm’). Their preparation, structure, and properties are given in this paper. Experimental Section Ligands. N,N’-Di-8-quinolylethylenediaminewas prepared according to the method described by Jensen and Nielsen.16 The optically active analogues were prepared as stated previously.’* The structures and the abbreviations of ligands are shown in Figure 1. [Co(acac)(dqen’)~lO,. A benzene solution of dqen (0.62 g in 10 cm3) was refluxed with a mixture of [Co(acac),] (0.71 g) and LiC1O4.3H2O (0.64 g) in ethanol (20 cm3) for 1 h. The deep green color changed to intense purple during the course of the reaction. The solution was set aside a t room temperature overnight to give black crystals, which were filtered off, washed with ethanol and diethyl ether, and air-dried; yield 0.92 g. [Co(acac)(R-dqpn’)]C104. This compound was prepared similarly by use of R-dqpn in place of dqen; yield 0.71 g. [Co(acac)(R,RRdqchxn’)]C1O4. A benzene solution of R,R-dqchxn (0.73 g in 10 cm3) was refluxed for 2 h with a mixture of [Co(acac),] (0.71 g) and LiCIO4.3H2O (0.64 g) in ethanol (20 cm3), evaporated to half-volume, and set aside at room temperature overnight. The dark purple crystals were filtered off, washed with diethyl ether, air-dried, and recrystallized from ethanol; yield 0.53 g. The analytical data of the complexes are summarized in Table I. The three complexes are soluble in polar organic solvents such as methanol, acetone, and dimethyl sulfoxide, are slightly soluble in benzene, and are insoluble in diethyl ether and hexane. They decompose on addition of water to give dark brown solutions. Structure of the Deprotonated [Co(acac)(R-dqpn’)]C104Studied by X-ray Crystallography. The crystal data are as follows: [Co(C~IH~~N,)(CSH~O~)IC~~~, [C26H&oN402+1 [c104-], fw 584.4, triclinic, space group P1, a = 11.112 (2) A, b = 13.299 ( 5 ) A, c = 9.275 (4) A, a = 106.06 (4)O, /3 = 88.72 (3)O, y = 85.87 (3)O, V = 1312.5 (7) A3, 2 = 2, Dmcasd = 1.48 g ~ m - D, ~ ,= 1.48 g cm-’, p(Mo Ka) = 0.812 mm-l. The X-ray intensity was measured with a crystal of dimensions 0.23 X 0.36 X 0.44 mm on a Rigaku automated four-circle diffractometer with Mo Ka radiation monochromated by a graphite plate. Among the total 7661 reflections (the +h,+k,+l set), those with 20 I60’ were measured by the 8-28 scan mode at a speed of 2’ min-I in 8. Thus, 4327 intensities with lFol > 3u(IFoI) were obtained and used for structure analysis. The intensities were corrected for Lorentz-polarization effects but not for absorption. The structure was solved by the heavy-atom method and refined by the block-diagonal least-squares method with anisotropic thermal parameters for non-hydrogen and hydrogen atoms, respectively. The where minimized function was R,(F) = [CwllFoI - IFc112/CwlFo12]’/2, + (0.0151F01)2.Among the weight was calculated by w-l = [U(~F,I)]~ 52 hydrogen atoms, the locations of 27 atoms were found by difference syntheses and those of the others estimated by calculations. The structure was disordered. There were three possible positions for the methyl C atom in the propylenediamine moiety of R-dqpn.

0 1983 American Chemical Society

Inorganic Chemistry, Vol. 22, No. 14, 1983 2049

Co(II1) Complexes of Di-8-quinolyl Derivatives Table I. Elemental Analyses of the Complexesa

~~

~

% found (% calcd) complex perchlorate [ Co (acac)(dqen’)] C10 [Co(acac)(R-dqpn‘)]C10, [ Co(acac)(R,R-dqchxn‘)]ClO, For ligand abbreviations, see Figure 1.

C

H

N

c1

52.90 (52.56) 53.43 (53.38) 54.26 (54.14)

4.47 (4.41) 4.82 (4.78) 5.34 (5.13)

9.30 (9.79) 8.97 (9.37) 8.96 (8.70)

5.86 (6.22) 5.87 (6.07) 5.54 (5.69)

dqen

CH3 R-dqpn

Figure 2. ‘H NMR spectra of (a’) [Co(acac)(dqen’)]CI04, (b’) [Co(acac)(R-dqpn’)]C104,and (c’) [Co(acac)(R,R-dqchxn’)]C104. (a), (b), and (c) are the analogous spectra measured in 12 M DC1.

R,R-dqchxn

Figure 1. Structures and abbreviationsof ligands (deprotonated species are expressed by primes: dqen’, dqpn’, and dqchxn’).

The weight for these was estimated by the trial and error method so that the isotropic thermal parameter (a. 5.5 A*) became nearly equal. The population parameters for C(C10)1, C(C10)2, C(C11), C(COlO), C(CO11)1,andC(C011)2are0.18,0.41,0.41,0.18,0.45,and0.37, respectively, where the atom notation is shown in Figure 8. The final R(F) and R,(F) values are 0.057 and 0.067, respectively. The positional and the equivalent isotropic thermal parameters are listed in Table 11. The absolute configuration of the complex cations was determined on the basis of the known absolute configurationof R-dqpn. The separately refined enantiomericstructure gave the same R factors as those of the original structure because the crystal structure has approximately the center of inversion. The calculation was performed by a FACOM 230-48 and a FACOM M-160F computer at the Institute for Solid State Physics, University of Tokyo, with the Universal Crystallographic Computation Program System UNICS 1 1 1 . l ~ Measurements. The pK, values of the coordinated secondary amine in the complexes were determined spectroscopicallyin ethanol, Le., by the analysis of the absorbance at 500 nm vs. acid concentration curves. The visible and ultraviolet absorption, CD, and ‘HNMR spectra were recorded with a Shimadzu Double 40-R spectrophotometer, a Jasco 5-20 spectropolarimeter, and a JEOL FX-100 spectrometer, respectively, at room temperature. Results Preparation of the Complexes. Several attempts to prepare cobalt(II1) complexes with the dqdm ligands were unsuccessful in aqueous solution. Reaction of tris(acety1acetonato)cobalt(II1) with these ligands in a mixture of benzene and ethanol, however, gave an intense purple solution, from which black or dark purple diamagnetic complexes were isolated as perchlorates. The analytical data given in Table I conform to those for salts consisting of univalent cations and per(19) Sakurai, T.; Kobayashi, K.Rikogoku Kenkyusho Hokoku 1979, 55, 69. (20) “International Tables for X-ray Crystallography”;Kynoch Press: Birmingham, England, 1974; Vol. IV.

chlorate. Since the central metal ion of all the complexes is diamagnetic cobalt(III), the quadridentate ligand must coordinate in the deprotonated form, [Co(acac)(dqdm’)]+. The corresponding parent complexes with neutral ligands were readily formed on addition of acid in organic solvents but isolated with difficulty. NMR Spectra. The proton magnetic resonance signals of all the isolated complexes with both neutral and deprotonated quadridentate ligands were recorded in 12 M DCl and acetone-d,, respectively (Figure 2). All the complexes gave two sharp singlet peaks due to the acac- chelate moiety at about 2.0 ppm, indicating that the complexes have cis-@geometry in which the two methyl groups of acetylacetonate are nonequivalent. Two kinds of doublets ( J = 6.7 Hz) with an intensity ratio 5:4 were observed around 1.6 and 0.4 ppm for the R-dqpn complex in deprotonated form. These two peaks can be assigned to the methyl groups on the (R)-propylenediamine chelate moiety. When the complex was dissolved in acid solution, the spectral feature in the methyl region changed remarkably; Le., the methyl peaks at 0.4 ppm disappear while two methyl doublets appear at 1.80 and 1.44 ppm with the area ratio approximately 5: 1. Thus, the peaks at 0.4 ppm in the basic solution must be assigned to the methyl group adjacent to the amide nitrogen. Absorption and CD Spectra. The absorption and CD spectra are shown in Figures 3-5, and their numerical data are summarized in Table 111. Both absorption and CD spectra of the present complexes exhibit striking changes depending on the pH of the solution. The spectra measured in ethanol correspond to those of the complexes with deprotonated ligand, while those measured in ethanol saturated with hydrogen chloride correspond to those of the complexes with neutral ligands. All the deprotonated complexes show two intense absorption bands (log t N 3.0-3.5) in the visible region. The band shape and intensities are not similar to the normal d-d transition bands of cobalt(II1) complexes. On the other hand, the spectra of the complexes with neutral ligands in the same region have a single absorption band and their intensities are much less. The bands are assigned to the first d-d bands on the basis of the peak location and intensity. A remarkable spectral change due to protonation and deprotonation of the coordinated ligand was also observed in the ultraviolet region

Suzuki et al.

2050 Inorganic Chemistry, Vol. 22, No. 14, 1983

‘Oy“c------5.0

20

30

40 o;/3iC’,

Figure 3. Absorption spectra of [Co(acac)(dqen’)]C104in ethanol saturated with HCl (-) and in ethanol (---). 20

30

40 %i/;OJC”

logE

Figure 5. Absorption and CD spectra of [Co(acac)(R,Rdqchxn’)]ClO, in ethanol saturated with HCI (-) and in ethanol

5 .c

(---).

4.C

b

&rEr

3.c 8 6

2.0

4

1 2

0 -2 -L

Figure 4. Absorption and CD spectra of [Co(acac)(R-dqpn’)]C104 in ethanol saturated with HCl (-) and in ethanol (---) and intermediate spectra (- * -). where the ligand T-A* absorption is predominant. The remarkable change in the absorption spectra is accompanied by the change in C D over the whole wavelength region. The complexes with deprotonated ligands (R-dqpn’ and R,R-dqchxn’) give intense CD peaks, positive and negative from longer to shorter wavelength, in the visible region. The CD pattern remarkably changes on dissolution in acid media. The R-dqpn complex gives a single positive peak, and the R,R-dqchxn gives small negative peaks in the d-d transition

a

Figure 6. Unit cell structure of [Co(acac)(R-dqpn’)]C104 projected approximately parallel to the c axis. region. Both complexes show a sharp positive and a negative C D from longer to shorter wavelength around 30 000 cm-’, which should correspond to the exciton splitting of the T-T* transition of the quinoline rings.21 Such clear exciton C D bands are not observed for the complexes with deprotonated ligands. The spectrum gives a pattern intermediate between those of the protonated and the deprotonated R-dqpn complex on careful adjustment of pH (Figure 4). Isosbestic points are seen in neither the absorption nor the CD spectra, indicating that several species other than those with the two limiting structures may be present in the solution. Crystal Structure of [Co(acac) ( R-dqpn’)]C104. Figure 6 shows the crystal structure projected approximately parallel to the c axis. There are two crystallographically independent complex cations and two perchlorate ions in the unit cell. Perspective drawings of the two complex cations are given in Figure 7. The absolute configurations of complexes 1 and 2 are A and A, respectively. The quadridentate ligand R-dqpn’ (21) Bosnich, B. Acc. Chem. Res. 1969, 2, 266

Inorganic Chemistry, Vol. 22, No. 14, 1983 2051

Co(II1) Complexes of Di-8-quinolyl Derivatives

Table 11. Positional Parameters ( X l o 4 ;for H, X l o 3 ) and Equivalent Isotropic Thermal Parameters Cl(1)

6793 (2) 6974 i 7 j 7337 (11) 5549 (8) 7182 (11) -2604 (2) -2210 (17) -2124 (18) -3764 (12) -2767 (13) 0 -1643 (5) 447 (4) 577 (6) 1613 (6) -337 (6) -418 (6) 56 (8) 539 (9) 1717 (9) 2361 (8) 1769 (6) 2332 (7) 3516 (7) 4100 (8) 3571 (8) 1794 (11) 944 (9) -389 (10) -776 (12) -1312 (9) -1374 (7) -866 (7) -942 (7) -1493 (8) -1962 (9) -1937 (8) -3291 (9) -2112 (8) -1422 (7) -201 (8) 346 (8) 4145 (1) 5794 (5) 3741 (6) 3580 (6) 2546 (6) 4386 (7) 4555 (6) 4229 (7) 3655 (10) 2532 (10) 1901 (8) 2467 (8) 1907 (7) 785 (8) 203 (8) 709 (10) 2290 (6) 3216 (10) 4538 (10)

5364 (2) 6062 (7) 4311 (8) 5271 (11) 5565 (6) 120 (2) -295 (11) 914 (10) 275 (14) -693 (9) 0 -281 (4) - 1246 (4) -675 (5) 307 (6) 775 (5) 1273 (5) -1232 (8) -1653 (8) -1452 (9) -877 (7) -477 (6) 106 (6) 313 (8) -77 (8) -595 (10) 1235 (12) 733 (8) 1510 (8) 2501 (8) 3232 (9) 3065 (7) 2090 (6) 1871 (7) 2590 (8) 3557 (7) 3884 (7) -1234 (9) -1179 (6) -1963 (6) -1998 (8) -2892 (7) 5493 (1) 5786 (4) 6726 (5) 6153 (5) 5128 (5) 4661 (7) 4134 (5) 6718 (7) 7045 (9) 6841 (9) 6175 (8) 5920 (8) 5309 (7) 4938 (9) 5217 (9) 5938 (9) 4512 (6) 4450 (1 2) 3885 (8)

7725 (3) 6880 (9) 6947 (9) 7820 (15) 9166 (10) -5162 (3) -6537 (12) -4605 (14) -5402 (24) -4537 (15) 0 -276 (7) 593 (6) -2026 (7) 340 (8) 2160 (7) -397 (8) -3200 (11) -4561 (9) -4795 (10) -3654 (10) -2259 (8) -942 (10) -1120 (11) -2674 (12) -3800 (11) 1650 (14) 2806 (9) -1740 (12) -1959 (16) -689 (14) 487 (13) 734 (8) 2179 (11) 3341 (11) 3124 (17) 1842 (15) -810 (12) -374 (10) 105 (9) 511 (9) 1064 (10) 2513 (1) 2869 (6) 1930 (7) 4583 (7) 2285 (7) 429 (8) 2985 (7) 5687 (9) 7221 (11) 7469 (11) 6295 (11) 4797 (11) 3567 (10) 3803 (11) 5100 (12) 6504 (15) 815 (8) -348 (12) 4237 (11)

5.7 (0.1) 8.8 (0.4) 11.8 (0.4) 13.7 (0.6) 11.5 (0.4) 5.8 (0.1) 21.7 (0.9) 20.0 (0.9) 20.9 (1.1) 14.6 (0.6) 3.6 (0.1) 4.6 (0.2) 4.0 (0.2) 3.9 (0.2) 4.2 (0.2) 4.0 (0.2) 4.2 (0.2) 5.0 (0.3) 5.5 (0.3) 6.1 (0.3) 4.4 (0.3) 3.4 (0.2) 3.9 (0.2) 5.3 (0.3) 6.0 (0.4) 6.8 (0.4) 8.9 (0.6) 5.1 (0.3) 5.8 (0.3) 8.3 (0.5) 7.1 (0.4) 6.1 (0.3) 3.6 (0.2) 5.1 (0.3) 6.3 (0.3) 9.1 (0.5) 7.2 (0.5) 6.4 (0.3) 4.6 (0.3) 4.2 (0.3) 5.0 (0.3) 4.9 (0.3) 3.5 (0.1) 3.8 (0.2) 5.3 (0.2) 3.9 (0.2) 3.6 (0.2) 5.6 (0.2) 3.8 (0.2) 4.7 (0.2) 6.4 (0.3) 6.6 (0.3) 5.4 (0.3) 5.0 (0.3) 4.5 (0.3) 5.6 (0.3) 6.5 (0.4) 7.9 (0.4) 3.1 (0.2) 8.2 (0.4) 5.7 (0.3)

C(013) C(014) C(015) C(016) C(017) C(018) C(019) C(020) C(021) C(022) C(023) C(024) C(025) C(C10) l a C(C 10)2a C(C1 l)a C(C01 0)a c(c011)la C(C011)2,3 HW3) H(C 1) H(C2) HC3) H(C7) H(C8) HC9) H(C11) H(C12) H(C13) H(C 14) H(C18) H(C19) H(C20) H(C21)l H(C21)2 H(C21)3 H(C23) H(C25)l H(C25)2 H(C25)3 H(N03) H(CO1) H(C02) H(C03) H(C07) H(C08) H(C09) H(CO10) H(C012) H(C0 13) H (CO 14) H(CO18) H(CO19) H(C0 20) H(C021) 1 H(C021)2 H(C021)3 H(C023) H(C025)l H(C025)2 H(C0 25 )3

4946 (11) 5391 (10) 5520 (7) 5050 (7) 5002 (7) 5567 (8) 6145 (9) 6043 (7) 7513 (9) 6176 (7) 5574 (8) 4444 (7) 3904 (9) 2590 (50) 1916 (22) 1108 (21) 1952 (49) 2903 (20) 3029 (24) -78 (7) -73 (7) 22 (6) 206 (8) 379 (6) 501 (6) 402 (8) 138 (6) -4 (6) -62 (7) -145 (7) -143 (7) -241 (8) -234 (8) -357 (6) -383 (8) -331 (7) -182 (7) 2 (7) 124 (8) 55 (8) 490 (7) 495 (6) 414 (7) 217 (8) 36 (8) -62 (8) 28 (6) 140 (7) 437 (6) 481 (7) 589 (8) 557 (7) 634 (7) 639 (8) 774 (8) 784 (6) 812 (9) 596 (8) 327 (7) 450 (7) 312 (8)

a Population parameters of the disordered methylC atoms: C(C10)1, 0.18;C(C10)2,0.41;C(C11), C(C011)2,0.37.

is coordinated to the Co"' ions in cis-@form in both cations. The observed electron density distribution was not reasonably interpreted without taking structural disorder into account. Edge-on views of the central chelate rings of cations 1 and 2 are shown in Figure 8. The hatched spheres in the figures denote the possible locations of disordered methyl C atoms. Two of them are attached to C( 10) and one to C( 11) of complex 1, whereas two are bonded to C(O11) and one to C(O10) of complex 2. The isotopic thermal parameters of C(l0) and C(O11) are 8.9 and

2928 (10) 2152 (7) 2391 (6) 3422 (6) 3726 (6) 3075 (7) 2115 (8) 1792 (6) 6768 (8) 6627 (7) 7525 (7) 7454 (6) 8432 (8) 911 (43) 2029 (19) 1596 (19) 3417 (43) 5013 (17) 4072 (21) 43 (6) -135 (6) -232 (6) -192 (7) 73 (5) 14 (6) -85 (7) 2 (5) 98 (5) 260 (6) 395 (6) 256 (6) 414 (7) 465 (7) -173 (5) -94 (7) -115 (6) -266 (6) -361 (6) -319 (7) -263 (6) 505 (6) 676 (6) 745 (6) 716 (7) 443 (7) 483 (7) 620 ( 5 ) 478 (6) 441 (6) 261 (6) 155 (7) 336 (6) 173 (6) 102 (7) 735 (7) 631 (6) 633 (8) 824 (7) 822 (6) 891 (6) 877 (7)

4336 (11) 3184 (17) 1614 (10) 1553 (11) 325 (9) -982 (11) -971 (10) 299 (12) 3339 (17) 2866 (9) 2648 (1 1) 2059 (9) 1701 (12) 2034 (62) 1972 (28) 4466 (27) 665 (62) -1157 (24) -1821 (30) 259 (8) -279 (8) -528 (8) -578 (10) -27 (8) -299 (8) -480 (10) 288 (7) -250 (7) -309 (9) -71 (9) 447 (9) 399 (10) 175 (10) -69 (7) -31 (10) -190 (9) 21 (9) 36 (8) 52 (10) 224 (9) -16 (9) 553 (8) 821 (9) 858 (10) 290 (9) 505 (9) 772 (7) 44 (9) 506 (8) 517 (8) 343 (10) -198 (9) -161 (9) 25 (10) 340 (10) 376 (8) 230 (11) 295 (10) 115 (9) 132 (9) 251 (10)

6.9 (0.4) 8.5 (0.5) 4.3 (0.3) 4.5 (0.3) 3.7 (0.2) 5.3 (0.3) 6.0 (0.3) 5.2 (0.4) 7.8 (0.5) 4.5 (0.3) 4.9 (0.3) 3.8 (0.3) 5.8 (0.4) 5.6 (1.2) 5.5 (0.5) 5.5 (0.5) 5.5 (1.2) 5.4 (0.5) 5.4 (0.6) 4.4 (1.8) 4.6 (1.9) 4.0 (1.7) 6.5 (2.2) 3.6 (1.6) 4.1 (1.7) 6.5 (2.2) 3.6 (1.6) 3.1 (1.5) 5.8 (2.1) 5.5 (2.0) 5.5 (2.0) 7.0 (2.4) 6.6 (2.2) 3.3 (1.5) 7.4 (2.5) 6.1 (2.2) 5.7 (2.1) 4.7 (1.9) 6.9 (2.4) 6.3 (2.2) 5.6 (2.0) 4.1 (1.7) 4.9 (1.9) 7.1 (2.4) 6.3 (2.2) 6.5 (2.3) 2.8 (1.4) 5.1 (1.9) 4.4 (1.8) 4.5 (1.8) 6.6 (2.3) 5.3 (2.0) 4.8 (1.8) 6.4 (2.2) 6.9 (2.4) 4.1 (1.7) 8.8 (2.8) 6.1 (2.2) 5.5 (2.0) 5.2 (2.0) 7.5 (2.5)

0.41; C(COlO), O.l8;C(COll)l, 0.45;

8.2 A*, respectively. On the other hand, those of C( 11) and C(O10) are 5.1 and 3.1 A*, respectively. The relatively large values for the former suggest the positional disorder of C( 10) and C(O11) atoms, which is related to the orientation of the disordered methyl groups on them. There is an overall trend that the nitrogen p to the methyl group in the ( R ) propylenediamine moiety is preferentially deprotonated over the cy-nitrogen by a factor of 1.5. The bond distances and angles within the (R)-propylenediamine chelate moieties of complexes 1 and 2 are listed in

Suzuki et al.

2052 Inorganic Chemistry, Vol. 22, No. 14, 1983 Table 111. Absorption (AB) and Circular Dichroism (CD) Spectral Data complex

solvent

[Co(acac)(dqen)] ’+

ethanol-HCla

[ Co(acac)(dqen’)]+

ethanol

[ Co(acac) (R-dqpn) ] *+

ethanol-HC1

AB em-’ (log E ) 19.80 (2.45) 31.64 (4.27j 32.79 (4.27) 44.64 (4.85) 15.63 shb (2.84) 20.20 (3.53) 27.03 (3.60) 31.75 sh (3.94) 37.31 (4.43) 44.25 (4.72) 19.61 (2.53) 31.65 (4.38) 32.79 (4.38)

ethanol

[Co(acac)(Rdqpn’)]

+

[ Co(acac)(R,R-dqchxn)] ’+

[Co(acac)(R,R-dqchxn’)]

+

ethanol-HC1

ethanol

43.67 (4.60) 15.38 (2.88) 20.20 (3.56) 27.03 (3.50) 31.75 sh (4.08) 37.31 (4.56) 44.64 (5.20) 14.93 sh (1.94) 20.41 (2.78) 31.75 (4.34) 32.47 (4.34) 35.09 sh (4.29) 43.10 (4.87) 15.63 (3.00) 20.66 (3.56) 26.66 sh (3.56) 31.75 sh (4.11) 37.74 (4.55) 44.25 (4.92)

a

Ethanol saturated with HCl.

CD cm-’ (€1 - er)

19.15 26.18 29.15 30.86 35.71 41.67 15.87 21.05

(+1.74) (-1.35) (+5.85) (-4.30) (-4.30) (+2.93) (+4.30) (-7.38)

34.01 (-3.61) 37.88 (+7.90) 42.02 (-1.6.20) 17.24 (t0.28) 19.42 (-0.40) 22.22 (-0.50) 25.00 sh (+0.48) 29.41 (+11.6) 32.05 (-6.60) 34.48 (-9.00) 40.00 (+24.6) 15.87 (+8.50) 21.05 (-19.7) 30.49 (+1S O ) 32.26 (-3.78) 34.97 (-3.40) 37.59 (+13.2) 40.65 (+9.50) 42.74 (-4.30)

sh = shoulder band.

Table IV. The bond distances involving the disordered methyl carbons are irregular; i.e., those on C( 10) and C(011) are too short, while those on C ( 11) and C(O10) are too long. This fact is due to the improper position of C atoms in the fivemembered rings and is more marked in complex 1. The long C( 10)-C( 11) distance (1.7 1 A) seems to be due to the error introduced by the high correlation of the parameter with the large thermal motion of the C(10) atom, which also brings about the conformational change of the chelate ring. For the same reason, the distorted bond angle N(2)-C(10)-C( 11) (90.7’) is not significant. The sums of the three bond angles around the N atoms N(2) and N(02) in complexes 1 and 2, respectively, are 347 and 358O. These values suggest sp2 hybridization, and these two N atoms seem to be deprotonated. They are the secondary N atoms shared by the two meridionally linked chelate rings. On the other hand, the sums of the three bond angles around N(3) (in complex 1) and N(03) (in complex 2) are 322 and 333O, respectively, and hydrogen atoms on them are found on a difference-density map. Each of them is shared by two five-membered rings, which are facial to each other. The mean value of Co-N(2) and Co-N(02) distances is 1.879 (7) A, which is shorter by 0.1 A than that of Co-N(3) and Co-N(03), suggesting an increased covalency between Co and -N--. Discussion Deprotonation of Coordinated Quinolylamines. Cobalt(II1) complexes with deprotonated amines have been synthesized with the following types of ligands: (i) Schiff bases formed between o-aminobenzaldehyde and ammonia22or propylene-

Table IV. Bond Lengths (A) and Angles (deg) within the Central Chelate Rings of Complexes 1 and 2 1

2

Co-N( 2) Co-N(3) N(2)-C(10) N ( 3 I - W 1) C(lO)-C(ll) C(10)-C(C10) 1 C(1O)-c(C 10)2 C(1 l ) - C ( C l l ) C(01 O)-c(COlO) C(011)-C(CO11)1 C(011)-C(CO11)2

1.881 (6) 1.996 (6) 1.503 (14) 1.560 (12) 1.712 (18) 1.07 (6) 1.04 (3) 1.67 (2)

1.877 (7) 1.946 (7) 1.429 (9) 1.508 (13) 1.455 (13)

N( 2)-Co-N( 3) Co-N(2)